Integrated surgical staple retainer for a full thickness resectioning device

ABSTRACT

The present invention is directed to a full-thickness resection system comprising a flexible endoscope and a stapling mechanism, wherein the endoscope is slidably received through at least a portion of the stapling mechanism. The stapling mechanism includes an anvil and a stapling head mounted to the anvil so that the anvil and the stapling head are moveable with respect to one another. A position adjusting mechanism is provided for moving the anvil and the stapling head relative to one another. 
     An integrated surgical retainer for use in the full thickness resectioning device is described. The integrated surgical staple retainer comprises a calibrating portion, a retaining portion, and a grasping portion. The calibrating portion defines a circular opening which has a diameter substantially equal to a diameter of a working channel of the full thickness resectioning device. The retaining portion has a lower surface adapted to limit movement of the surgical staples in the full thickness resectioning device and is adjacent to the calibrating portion of the integrated surgical staple retainer.

This application is a Division of prior U.S. patent application Ser. No. 09/835,480 filed Apr. 17, 2001 entiled “Integrate Surgical Staple Retainer for a full thickness Resectioning Device” now U.S. Pat. No. 6,585,144 which is a Continuation-In-Part of U.S. Ser. No. 09/694,894 filed Oct. 25, 2000 now U.S. Pat. No. 6,241,140 which is a Continuation U.S. Ser. No. 09/316,674 filed May 21, 1999 now U.S. Pat. No. 6,179,195 which is a Division of U.S. Ser. No. 09/100,393 filed Jun. 19, 1998 entitled “Method and Device for Full Thickness Resectioning of an Organ now U.S. Pat. No. 6,126,058. All applications are expressly incorporated herein, in their entirety, by reference.

FIELD OF INVENTION

The present invention relates to full thickness resection devices (FTRD's) for performing localized resections of lesions in tubular organs, particularly the colon.

BACKGROUND INFORMATION

A resection procedure involves excising a portion of an organ, approximating the surrounding tissue together to close up the hole created by the excision, and removing the excess tissue. Various conventional devices and procedures are available for resectioning lesions in tubular organs.

For example, several known resection devices and procedures requires at least one incision in an area near the portion of the organ to be excised for access to the lesion or treatment site (because, for example, the resectioning device may lack steering and/or viewing capabilities). Thus, the incision is required to allow the physician to access the organ section to be excised and guide the device to that section. Alternatively, when the organ section to be excised is beyond the reach of the surgical device, or the surgical device is not flexible enough to wind through the organ to the site to be excised, an incision will be required to position the device for the procedure. Of course, these incisions are painful and may involve a partial or entire loss of mobility while recuperating from the incision, in addition to recovering from the tubular resectioning procedure itself. In addition, the time required to recover from such a procedure is often longer than for procedures which do not require incisions.

One type of conventional resection procedure utilizes a circular stapling instrument in a tubular section of a tubular organ is excised, resulting in the tubular organ being separated into a first segment and a second segment. The end sections of the first and second segments are then individually tied in a purse string fashion, approximated, stapled, and the “purse stringed” end sections are then cut off. In this full circle resectioning procedure, at least one separate invasive incision must be made near the section to be excised in order to cut and individually tie the separate end sections of the organ. Also, a separate incision is necessary to place one part of the resectioning device in the first segment and a corresponding second part of the device in the second segment so that the device can then bring the first and second segments together to re-attach the organ sections back together. A first of these separate parts may generally include a staple firing mechanism while the second part includes an anvil for forming the staples. Thus, this type of resectioning procedure involves the drawbacks mentioned above in regard to procedures requiring invasive incisions. In addition, the separation of the organ into two segments creates the risk of spillage of non-sterile bowel contents into the sterile body cavity, which can cause severe infection and possibly death.

An alternative resectioning device includes a stapling and cutting assembly on a shaft which can be bent or formed into a desired shape and then inserted into a patient's body cavity. Once the shaft has been bent into the desired shape, the rigidity of the shaft ensures that shape is maintained throughout the operation. This arrangement limits the effective operating range of the device as the bending of the shaft into the desired shape before insertion and the rigidity of the shaft once bent require the physician to ascertain the location of the organ section to be removed before insertion, and to deform the shaft accordingly. Furthermore, the rigidity of the shaft makes it difficult to reach remote areas in the organ—particularly those areas which must be reached by a winding and/or circuitous route (e.g., sigmoid colon). Thus, an incision may be required near the organ section to be excised in order to position the device at the organ section to be excised.

In addition, conventional stapling devices include staple retainers which serve only a limited function. Conventional staple retainers which accompany stapling devices are generally intended to only secure the staples during shipment. This can be problematic as the surgeon has to use a separate instrument to gauge the diameter of an endoscope to ensure the endoscope is not too large to fit through the working channel of the resectioning device. The separate endoscope gauge could easily be lost during unpacking of the resectioning device since it is not attached to the device. In addition, there is an additional cost in manufacturing a separate endoscope gauge. There is thus a need for an integrated staple retainer which is capable of securing staples and gauging an endoscope and which can be placed within a resectioning device.

The full thickness resectioning device presents a unique challenge with the need to introduce a flexible endoscope through an internal lumen of the device. Flexible endoscopes are manufactured and repaired by numerous entities with little regard for standardization of maximum outer specification. The cost of repairing a damaged endoscope is high and the attempted forced introduction of a flexible endoscope into the full thickness resectioning device will damage the endoscope. There is, therefore, a strong need for a means of insuring that only endoscopes of an appropriate diameter are utilized.

SUMMARY OF THE INVENTION

The present invention is directed to a full-thickness resection system comprising a flexible endoscope and a stapling mechanism, wherein the endoscope is slidably received through at least a portion of the stapling mechanism. The stapling mechanism includes an anvil and a stapling head mounted to the anvil so that the anvil and the stapling head are moveable with respect to one another between a tissue receiving position and a stapling position and wherein a gap formed between the stapling head and the anvil is larger in the tissue receiving position than it is in the stapling position. A position adjusting mechanism is provided for moving the anvil and the stapling head between the tissue receiving and stapling positions and a staple firing mechanism sequentially fires a plurality of staples from the stapling head across the gap against the anvil and through any tissue received in the gap and a knife cuts a portion of tissue received within the gap. A control unit which remains outside the body is coupled to the stapling mechanism for controlling operation of the position adjusting mechanism and the staple firing mechanism. An integrated surgical staple retainer and endoscope diameter gauge is provided to retain the staples in place during shipping of the FTRD, and to allow the user to conveniently check that the endoscope will fit through the FTRD.

In an exemplary embodiment, the current invention is directed to an integrated surgical staple retainer for use in a full thickness resectioning device. The integrated surgical staple retainer comprises a calibrating portion and a retaining portion. The calibrating portion defines a circular opening which has a diameter substantially equal to a diameter of a working channel of the full thickness resectioning device. The retaining portion has a surface adapted to limit movement of the surgical staples in the full thickness resectioning device. The retaining portion is adjacent to the calibrating portion of the integrated surgical staple retainer.

A different aspect of the current invention is directed to a method of gauging the outermost diameter of an endoscope for use in an integrated surgical staple retainer. The calibrating portion is removed from the FTRD and is slid over the outermost diameter of the endoscope.

Another aspect of the current invention is directed to a method of retaining staples in a full thickness resectioning device using an integrated surgical staple retainer. The retaining portion is placed between a proximal housing and an anvil member of a full thickness resectioning device. The distance between these two sections of the resectioning device is then minimized so that the integrated surgical staple retainer remains in position relative to the resectioning device.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a device according to a first embodiment of the present invention;

FIG. 2 shows the device of FIG. 1 mounted on a conventional endoscope;

FIG. 3 shows the device of FIG. 1 with a grasper mechanism extending therefrom;

FIG. 4 shows a cutaway of the device of FIG. 1 showing a drive mechanism thereof;

FIG. 5 shows a cutaway of the device of FIG. 1 showing an actuating mechanism;

FIG. 6 shows a detailed view of the wedge used in the actuating mechanism of FIG. 5;

FIG. 7 shows a cut-away view of a working head assembly of the device of FIG. 1;

FIG. 8 shows a rear cover plate of the working head assembly of FIG. 7;

FIG. 9 a shows a mechanism for restricting motion of a drive shaft of the device of FIG. 1;

FIG. 9 b shows a first coupling arrangement for a drive cable and a drive shaft in the device of FIG. 1;

FIG. 9 c shows a second coupling arrangement for the drive cable and the drive shaft in the device of FIG. 1;

FIG. 9 d shows a perspective cut-away view of a sheath of the device of FIG. 1;

FIG. 10 a shows a perspective view of an alternative construction of the wedge of FIG. 6;

FIG. 10 b shows a cut-away view of the wedge of FIG. 10 a;

FIG. 10 c shows a blade portion corresponding to the wedge of FIG. 10 a;

FIG. 11 shows a device according to a second embodiment of the present invention;

FIG. 12 shows a device according to a third embodiment of the present invention;

FIG. 13 shows a device according to a fourth embodiment of the present invention;

FIG. 14 a shows a device according to a fifth embodiment of the present invention;

FIG. 14 b shows a detailed cut-away view of the device of FIG. 14 a and a conventional endoscope;

FIG. 15 shows a control handle for use with the devices according to the present invention;

FIG. 16 shows a blade housing arrangement for use with a device according to the present invention;

FIG. 17 shows a first arrangement of a blade shield for use with a device according to the present invention;

FIG. 18 shows a second arrangement of the blade shield for use with a device according to the present invention;

FIG. 19 a shows a third arrangement of the blade shield for use with a device according to the present invention;

FIG. 19 b shows a tissue blocker of the blade shield of FIG. 19 a;

FIG. 19 c shows a distal end of a proximal housing of the device of FIG. 19 a; and

FIG. 20 shows a device according to a sixth embodiment of the present invention.

FIG. 21 shows a device according to a seventh embodiment of the present invention.

FIG. 22 shows a first perspective view of the device of FIG. 21.

FIG. 23 shows a second perspective view of the device of FIG. 21.

FIG. 23 a shows a third perspective view of the device of FIG. 21.

FIG. 24 shows a side cut-away view of the device of FIG. 21.

FIG. 25 shows a fourth perspective view of the device of FIG. 21.

FIG. 26 shows a cut-away view of an exemplary stapler member of the device of FIG. 1.

FIG. 27 shows a perspective view of an integrated surgical staple retainer according to a first embodiment of the present invention

FIG. 28 shows a perspective view of an integrated surgical staple retainer according to a second embodiment of the present invention.

FIG. 29 shows a perspective view of an integrated surgical staple retainer in relation to a full thickness resectioning device according to an embodiment of the present invention.

FIG. 30 shows a perspective view of an integrated surgical staple retainer placed within a full thickness resectioning device according to an embodiment of the present invention.

FIG. 31 shows a perspective view of a calibrating portion of an integrated surgical staple retainer gauging the outermost diameter of an endoscope according to an embodiment of the present invention.

DETAILED DESCRIPTION

As shown in FIGS. 1 and 2, an apparatus according to a first embodiment of the present invention comprises a working head assembly 2 which may preferably be connected to a distal end 4 a of a sheath 4. The proximal end 4 b of the sheath 4 may preferably be connected to a control handle 6.

In operation, the entire apparatus is mounted onto an endoscope 8 by passing the endoscope 8 through the control handle 6, the sheath 4, and the working head assembly 2, as shown in FIG. 2. The endoscope 8 is then inserted into a body orifice to locate a lesion in the tubular organ under visual observation (usually while insufflating the organ). Once the lesion has been located, the working head assembly 2 and the sheath 4 are slidably advanced along the endoscope 8 into the tubular organ until the working head assembly 2 is in a desired position adjacent to the lesion. Those skilled in the art will understand that in an alternative embodiment, the working head assembly 2 may also be detachably coupled to a distal end of the endoscope 8, and the entire arrangement may then be inserted into the body orifice under visual observation.

As shown in FIG. 1, the working head assembly 2 comprises an anvil member 10 coupled to a distal end 12 a of a proximal housing 12. The anvil member 10 has a substantially crescent-shaped cross-section (i.e., the outer edge 18 of the anvil member 10 substantially forms a portion of a first circle with a second smaller circular cut-out 13 formed within the first circle) with a proximal face 14 and a smaller distal face 16. The cut-out 13 of the anvil member 10 is included to allow the endoscope 8 to be slid through the entire working head assembly 2 so that the endoscope 8 may be advanced into the body passage allowing the working head assembly 2 to later be advanced into the body to the lesion. In addition, the cut-out 13 also provides forward vision via the endoscope 8. Thus, any shape of the cut-out 13 may be selected which is large enough to accommodate the endoscope 8, with a larger cut-out providing a larger field of vision. An outer surface 18 of the anvil member 10 extends substantially parallel to a central axis of the working head assembly 2 while the proximal and distal faces 14, 18 of the anvil member 10 extend in planes substantially perpendicular to the central axis. The outer surface 18 is joined to the distal face 16 by a tapered portion 5.

As shown in FIG. 3, the proximal face 14 of the anvil member 10 includes a first cavity 37 and a rim 41 encircling the first cavity 37. A plurality of staple forming grooves 19 are arranged in two offset rows on the rim 41 of the anvil member 10 and a circular guiding slit 21 extends radially within the rows of grooves 19. The rim 41 protrudes from the remainder of the proximal face 14 so that a shallow cavity is formed on the proximal face 14.

The anvil member 10 is coupled to the proximal housing 12 by means of two mounting shafts 20 a and 20 b, which may preferably be substantially cylindrical. Each mounting shaft 20 a, 20 b is coupled to the proximal face 14 of the anvil member 10 on a respective one of two horns 22 a, 22 b formed by the crescent-shaped anvil member 10. Although the anvil member 10 is shown fixedly coupled to the mounting shafts 20 a, 20 b, those skilled in the art will understand that the anvil member 10 may also be pivotally coupled to the mounting shafts 20 a, 20 b in order to provide a greater field of vision through the endoscope 8 as shown in FIG. 3 a. In this pivoted-type arrangement, the anvil member 10 is angled in a first configuration so that the horns 22 a, 22 b are closer to the distal end 12 a of the proximal housing than the rest of the anvil member 10. Then, as the anvil member 10 is drawn towards the distal end 12 a of the proximal housing 12, the anvil member 10 would be pressed against the distal end 12 a beginning with the horns 22 a, 22 b, which would cause the anvil member 10 to pivot until the proximal face 14 of the anvil member 10 is parallel to the distal end 12 a.

As shown in FIG. 1, the mounting shafts 20 a, 20 b are slidably received in mounting holes 26 a, 26 b, which have a size and shape substantially corresponding to the size and shape of the mounting shafts 20 a, 20 b and which run axially through the proximal housing 12. The mounting shafts 20 a, 20 b are preferably movable axially proximally and distally within the mounting holes 26 a, 26 b between a proximal most position in which a tissue gripping gap of a first predetermined width is formed between the rim 41 and the distal end 12 a of the proximal housing 12, and a distal most position in which a tissue receiving gap of a larger second predetermined width is formed between the rim 41 and the distal end 12 a of the proximal housing 12. The second predetermined width should preferably be more than twice the thickness of a wall of the organ being resectioned so that a section of the tubular organ may be pulled into a resectioning position between the anvil member 10 and the proximal housing 12.

As shown in FIG. 4, the proximal end of at least one of the mounting shafts 20 a and 20 b is coupled to a drive mechanism 102 provided within the proximal housing 12. In a preferred embodiment, the drive mechanism 102 is composed of a yoke 103 and a drive shaft 105. The yoke 103 is preferably slidably received within the proximal housing 12 for longitudinal movement along the axis of the proximal housing 12 so that, when the anvil member 10 is in the proximal most position, the yoke 103 is in a corresponding proximal most position and, when the anvil member is in the distal most position, the yoke 103 is in a corresponding distal most position.

The yoke 103 may preferably be substantially semicircular with a substantially rectangular cross section. Although the semicircle formed by the yoke 103 in FIG. 4 forms substantially a quarter arc of a circle, the yoke 103 may form a larger semicircle based upon the interior accommodations of the proximal housing 12 and the position of the mounting shafts 20 a, 20 b. The mounting shaft 20 a may preferably be coupled to the yoke 103 at a first end 103 a of the yoke 103, and the mounting shaft 20 b may be coupled at a second end 103 b of the yoke 103. A shaft hole 107, having a diameter substantially corresponding to a diameter of a complementarily threaded distal end 105 a of the drive shaft 105, extends through the yoke 103 at a point substantially midway between the first end 103 a and second end 103 b. Thus, when the drive shaft 105 is rotated, the threaded distal end 105 a engages the shaft hole 107 to move the yoke 103 proximally or distally (in dependence upon the direction of rotation of the drive shaft 105).

The distal end 105 a of the drive shaft 105 should preferably be threaded over a first section 105 t substantially corresponding in length to at least the distance between the proximal and distal most yoke positions, while a remainder portion 105 r may have no threads thereon. The drive shaft 105 may have an increased cross-section in the areas immediately adjacent to the threaded first section 105 t (proximally and/or distally of section 105 t), thereby limiting the movement of the yoke 103 to the first section 105 t. Those skilled in the art will understand that the drive shaft 105 is preferably rotatably mounted within the proximal housing 12 so that it may only rotated and may not move relative to the proximal housing 12. The drive shaft 105 preferably extends to a proximal end 105 b which is coupled to a drive cable 100 which extends to the control handle 6 through the sheath 4. The drive cable 100 may preferably run axially along the peripheral interior of the sheath 4. Those skilled in the art will understand that the sheath 4 is preferably torsionally stiff to resist the torque forces from the drive cables rotating therein. However, the sheath 4 is longitudinally flexible to so that it may be slidably advanced along the endoscope 8, while minimizing interference with the operation of the endoscope 8 and trauma to surrounding tissue. The sheath 4 is preferably constructed similar to known endoscope insertion tubes, which are flexible yet allow the transfer of forces to swivel the distal end of the endoscope 8 in multiple directions and the torqueable rotation of the endoscope.

FIGS. 7-10 show a cutaway view of the working head assembly 2 in FIG. 1, in which the respective movements of the drive shaft 105 and the yoke 103 are restricted in the manner described above. As shown in FIG. 8, a pearshaped rear cover plate 460 may preferably be connected to the proximal end 12 b of the proximal housing 12. A first shaft hole 462 having a cross-sectional size substantially corresponding to the cross-sectional size of the drive shaft 105 is provided in a lower portion of the rear cover plate 460 for receiving the drive shaft 105 therethrough. Thus, the yoke 103 is restricted to only longitudinal movement in this arrangement because, the distal side of the yoke 103 is coupled to the mounting shafts 20 a, 20 b which are disposed in the mounting holes 26 a, 26 b, and the proximal side of the yoke 103 is coupled to the drive shaft 105 which is disposed in the first shaft hole 462.

As shown in FIG. 9 a, the movement of the drive shaft 105 may be restricted to only rotation movement about its axis by two washer-type devices 470 fixedly attached to the drive shaft 105 on either side of the rear cover plate 460. A similar result may be achieved by providing the drive shaft 105 with a larger cross-sectional size on either side of the rear cover plate 460 in relation to the portion of the drive shaft 105 within the rear cover plate 460. Alternatively, the cross section of a bulging portion 476 of the drive shaft 105 located substantially in the center of the rear cover plate 460 may be larger than the portions of the drive shaft 105 immediately adjacent to the bulging portion 476. The first shaft hole 462 may then have a center portion 474 with a larger cross-section than the rest of the first shaft hole 462 to accommodate the bulging portion 476 of the drive shaft 105.

FIG. 9 b shows a coupling arrangement between the drive cable 100 and the drive shaft 105 in which a proximal end 105 a of the shaft may have a D-shaped hole 105 h extending therethrough. A distal end 102 b of the drive cable 100 has a D-shape corresponding to the shape of the hole 105 h so that the distal end 102 b of the drive cable may be received within the hole 105 h in the drive shaft 105. FIG. 9 c shows an alternative coupling arrangement for coupling the drive cable 100 to the drive shaft 105 in which the hole 105 h in the proximal end 105 a of the drive shaft 105 a and the distal end 102 b of the drive cable 100 have corresponding squarish shapes. The single edge provided by the D-shapes in FIG. 9 b and the four edges provided by the squarish shapes in FIG. 9 c allow the drive cable 100 to transfer a rotational force to the drive shaft 105 with minimal slippage.

In operation, the user advances the endoscope 8, with the working head assembly 2 received there around, to a portion of tissue to be resectioned until the working head assembly 2 is in a desired position adjacent to the tissue to be resectioned. The user may then apply a force to the control handle 6 to rotate the drive cable 100 which in turn rotates the drive shaft 105 to advance the yoke 103 and the anvil member 10 distally away from the distal end 12 a of the proximal housing 12. As shown in FIG. 3 when the anvil member 10 has reached the distal most position, a known grasping device 108 is advanced through the sheath 4 and through the working head assembly 2 to enter the gap between the anvil member 10 and the distal end 12 a via one of the grasper holes 32 and 33. Although the device in FIG. 3 is shown using a duodenoscope as the endoscope 8, those skilled in the art will understand that other types of endoscopes may also be used, such as, for example, gastroscope, colonoscope, etc.

As shown in FIG. 1, at least the distal end 12 a of the proximal housing 12 preferably has a cross-section corresponding in size and shape to the proximal face 14 of the anvil member 10, including a cut-out 29 substantially corresponding in size and shape to the cutout 13 of anvil member 10. The cut-out 29 is provided to receive the endoscope 8 therein and allow the proximal housing 12 to be slidably advanced along the endoscope 8. Of course, those skilled in the art will understand that the shape of the outer surface of the working head assembly 2 may be selected in order to accommodate various desired resectioning shapes, and the shape of the anvil member 10 may preferably be selected to form a continuous surface when positioned adjacent to the proximal housing 12 to facilitate advancing the working head assembly to into and removing it from, body passages. It is preferable that the working head assembly have a maximum diameter at any point between 15 mm and 40 mm.

A tissue receiving cavity 30 is formed substantially centrally in the distal end 12 a of the proximal housing 12 to facilitate the drawing of sections of tubular organs into the gap between the anvil member 10 and the distal end 12 a. Those skilled in the art will understand that the depth of the cavity 30 may vary depending on the amount of tissue to be pulled into the cavity 30 and the size of the proximal housing 12. Two grasper holes 32 and 33 extend axially, preferably slightly off-center from the longitudinal axis of the proximal housing 12. In a preferred embodiment, the grasper holes 32 and 33 may each preferably receive a grasping device 108 advanced from the control handle 6, through the sheath 4, and through a respective one of the grasped holes 32 and 33.

In operation, either one or two grasping devices 108 may then be used to pull a section of the tubular organ between the anvil member 10 and the distal end 12 a of the proximal housing 12 and into the cavity 30. A third grasping device 108 may also be inserted through the working channel of the endoscope 8 to provide another means of positioning the organ section between the anvil member 10 and the proximal housing 12. Of course, those skilled in the art will understand that any desired instrument may be advanced to the gap between the anvil member 10 and the distal end 12 a through any of the grasped holes 32, 33 and the working channel of the endoscope 8.

A plurality of staple slits 34 are preferably disposed in two offset substantially circular rows extending along the periphery of the distal end 12 a of the proximal housing 12. The staple slits 34 extend from an area adjacent to the mounting shaft 26 a to an area adjacent to the other mounting shaft 26 b. The plurality of staple slits 34 may preferably be arranged so that when the anvil member 10 is in the proximal most position, each of the staple slits 34 is aligned with a corresponding one of the staple-forming grooves 19.

When the device is configured for operation, a plurality of staples is received within the working head assembly 2 with each of the staples being aligned with a respective one of the staple slits 34. The staples are then sequentially fired from the respective staple slits 34 by an actuating mechanism 104 (shown in FIG. 5) disposed in the proximal housing 12.

A substantially circular blade slit 36 extends substantially radially within the staple slits 34 so that, when the anvil is in the proximal most position, the blade slit 36 is aligned with the guiding slit 21 on the anvil member. As shown more clearly in FIG. 12, extensions 84 a and 84 b of the blade slit 36 extend into blade housings 74 a and 74 b, respectively, which project distally from the distal end 12 a of proximal housing 12. The blade housings 74 a and 74 b are preferably situated so that when the anvil member 10 is in its proximal Most position, the blade housings 74 a and 74 b contact portions 43 a and 43 b of the rim 41 of the anvil member 10. The extension of the blade housings 74 a and 74 b from the proximal housing 12 is preferably selected BO that when the blade housing devices 74 a and 74 b engage the remainder portions 43 a and 43 b of the rim 41 (thereby stopping a proximal movement of the anvil member 10 and defining the proximal most position thereof), a gap is formed between the anvil member 10 and the distal end 12 a of a length sufficient to allow the anvil member 10 to securely hold a portion of the organ against the proximal housing 12 without crushing and damaging the portion of the organ.

When positioned at one end of the blade slit 36 (i.e., in one of the extensions 84 a and 84 b), a cutting blade 202 is preferably completely enclosed within the respective one of the blade housing devices 74 a and 74 b and the guiding slit 21, so that the cutting blade 202 does not cut any tissue until the physician intentionally operates the blade 202. When the physician operates the blade 202, the blade 202 is driven from its initial position received within one of the extensions 84 a and 84 b around the blade slit 36 with its cutting edge facing a direction of movement, until the blade 202 is received into the other one of the extensions 84 a and 84 b. Thus, after a cutting operation has been performed, the blade 202 is once again prevented from inadvertently injuring the patient.

FIG. 6 shows a wedge 402, a first portion 402 a of which is non-rotatably coupled to an actuating shaft 400 so that rotation of the shaft 400 the wedge 402 rotates, preferably about the longitudinal axis of the working head assembly 2. The wedge 402 includes a blade handle 408 which extends from a first portion 408 a coupled to the wedge 402 to a second portion 408 b which is coupled to the blade 202 so that, when the wedge 402 is rotated, the blade 202 is rotated through the blade slit 36. The wedge 402 has a substantially bell-like cross-section when viewed axially, with a second portion 402 b extending radially outward from the first portion 402 a and, consequently, from the longitudinal axis of the shaft 400 which preferably coincides with the longitudinal axis of the working head assembly 2. A notch of varying depth is cut out of a radially outer portion of the second portion 402 b to form a cam surface 412 thereon. A first ramp section 412 a ramps up from a leading face 402 d of the wedge 402 to adjoin a second ramp section 412 b that ramps down to adjoin a rear face 402 e of the wedge 402. The wedge 402 is preferably arranged in the proximal housing 12 so that the cam surface 412 is substantially aligned with the staple slits 34.

A staple driver 472 extends substantially longitudinally, proximally from each of the staple slits 34 having toward the plane in which the wedge 402 rotates and each staple driver 472 is slidably received within the working head assembly 2 for motion between a distal most, staple driving position and a proximal most inoperative position. In the inoperative position, an upper end of each of the staple drivers 472 is completely received within the proximal housing 12, just proximal of a respective staple. The staple drivers 472 are preferably substantially rectangular in shape, although bottom edges 472 a thereof may more preferably be rounded. The length of the staple drivers 472 is preferably selected so that, in the inoperative position, the bottom surfaces 472 a extend into the plane of rotation of the wedge between the proximal and distal most extents of the first ramp portion 412 a. The bottom surfaces 472 a are, in the inoperative position, more preferably substantially aligned with the distal most projection of the of the cam surface 412 at the leading face 402 d. Thus in operation, the wedge 402 is rotated by the actuating shaft 400 so that the first ramp section 412 a of the cam surface 412 successively drives each of the staple drivers 472 into contact with a corresponding staple so that each staple driver 472 and its staple are driven distally through a respective one of the staple slits 34. This drives the staples across the gap from the distal end 12 a into the anvil member 10, through any tissue held between the anvil member 10 and the proximal housing 12, and into the corresponding staple forming grooves 19. Thus the section of the tissue gripped between the anvil member 10 and the proximal housing 12 is stapled in a pattern substantially the same as that formed by the staple slits 34 (i.e., substantially circular). At the same time, the blade 202 is rotated through the blade slit 36 to cut the tissue which has just been stapled through the rotation of the wedge 402.

After each of the plurality of staples has been fired, the wedge 402 may be driven in a reverse direction to reload a new plurality of staples. The wedge 402 may rotate in a direction opposite the staple firing direction without getting caught on any of the staple drivers 472 because the staple drivers are pushed out of the way by the second ramp section 412 b of the cam surface 412.

In operation, the user applies a force to the control handle 6 to rotate an actuating cable 450 about its longitudinal axis. This rotational force is transferred to the actuating shaft 400, which then rotates the wedge 402 around the longitudinal axis of the actuating cable 450. The first ramp section 412 a of the cam surface 412 of the wedge 402 then individually drives the staple drivers 472 distally as described above to staple the tissue received between the anvil member 10 and the proximal housing 12 with the cutting blade 202 lagging behind the fining of the stapling since the blade handle 408 is coupled to the rear face 402 e of the wedge.

FIG. 10 a shows an alternative configuration of the wedge 402 of FIG. 6 including a separate blade portion 420. The blade portion 420 is preferably rotatably coupled to the distal end 400 a of the actuating shaft 400 so that a rotation of the actuating shaft 400 about its longitudinal axis does not cause a corresponding rotation of the blade portion 420. As in FIG. 6, the wedge 202 of this apparatus is non-rotatably coupled to the distal end 400 a of the shaft 400.

The blade handle 408 of this apparatus, which is coupled to a peripheral edge 420 e of the blade portion 420, extends to the cutting portion of the blade 202. As described above, the cutting portion of the blade 202 extends past the distal end 12 a except when the blade 202 is received within one of the extensions 84 a and 84 b.

The wedge 402 substantially corresponds in shape and size to the wedge 402 of FIG. 6, except that the blade handle 408 is not coupled thereto. In addition, a locking shaft 402 h extends into a distal surface 402 t located as shown in FIG. 10 a so that when the blade portion 420 and the wedge portion 410 are aligned, the locking shaft 402 h and a locking dimple 414 (shown in FIG. 10 c) on the bottom face 420 b of the blade portion 420 are substantially aligned. As shown in FIG. 10 b, a spring 416 is received within the locking shaft 402 h with a proximal end of the spring coupled to the proximal end of the locking shaft 402 h. A locking ball 418 coupled to the distal end 416 b of the spring 416 is sized so that when a proximally directed force is applied to the locking ball 418, the locking ball 418 may be slidably received within the locking shaft 402 h. In addition, when no distally directed force is applied to the locking ball 418, the spring 416 preferably extends so that approximately one half (or more) of the locking ball 418 extends distally out of the locking shaft 402 h. Thus, when the wedge 402 is rotated toward the blade portion 420, the locking ball 418 is received in a cut-out 425 formed on the proximal surface 420 b of the blade portion 420. As shown in FIG. 10 c, the cut-out 425 slopes downward to adjoin the locking dimple 424 so that when the locking ball 418 is received, the slope of the cut-out 425 gradually pushes the locking ball 418 into the locking shaft 420 h. Then, when the wedge 402 moves into alignment with the blade portion 420, the locking ball 418 extends out of the locking shaft 402 h and enters the locking dimple 414 to couple the wedge 402 to the blade portion 420 so that a rotation of the wedge 402 causes a corresponding rotation of the blade portion 420.

A radial length B₁ between the peripheral edge 420 e of the blade portion 420 and the actuating shaft 400 may substantially correspond to a radial length W₁ between the wall 402 f of the wedge portion 410 and the actuating shaft. This places the blade handle 408 in substantially the same position, relative to the cam surface 402 c of the wedge portion 410, as in the previous embodiments. Of course, those skilled in the art will understand that it is important that the blade 408 should extend substantially distally to the blade slit 36 so that rotation of the blade portion 420 will cause a corresponding rotation of the blade 202 through the blade slit 36.

In operation, the wedge 402 is initially situated distally of one of the blade housings, e.g., 74 a while the blade portion 420 is situated distally of the blade housing 74 b with the blade 202 received in the blade housing 74 b. When the lesion tissue has been drawn into position between the distal end 12 a and the anvil member 10, the physician actuates the shaft 400 by applying a force at the control handle 6. This causes the wedge portion 410 to rotate distally of the staple slits 34, to sequentially drive each of the staple drivers 472 distally through the corresponding staple slit 34. When the wedge 402 has rotated fully into alignment with the blade portion 420 and the locking ball 418 is received into the locking dimple 414, the operator then operates the control handle 6 in the opposite direction to draw the blade 202 out of the blade housing 74 b to cut all of the tissue extending radially inward of the rows of staples. When the blade 202 is received in the other blade housing 74 a, the wall of the body passage is released and the lesion tissue remains within the gap between the distal end 12 a and the anvil member 10 held by the grasping devices 108. The lesion tissue may then be withdrawn from the body for analysis. This embodiment of the wedge 402 provides a safeguard in case the stapling process must be prematurely aborted due to, for example, a jam in one of the staple slits 34. Using this embodiment, the cutting process is not begun until all of the staples have been fired. Thus, it is possible to reduce the risk of cutting an opening in an organ which is not completely closed by the staples.

As shown in FIG. 5, the actuating mechanism 104 includes the actuating cable 450 which extends from a proximal end 450 a coupled to the control handle 6 to a distal end 450 b coupled to the proximal end 400 a of the actuating shaft 400. Those skilled in the art will understand that the wedge 402 should preferably be situated towards the distal end 12 a of the proximal housing 12 so that the yoke 103 does not interfere with rotation of the wedge 402 around the longitudinal axis of the actuating shaft 400 (discussed below) even when the yoke 103 is in its distal most position.

As shown in FIGS. 7-9 a, the rear cover plate 460 may preferably be coupled to the proximal end 12 b of the proximal housing 12. The proximal end 12 b of the proximal housing 12 is then connected to the sheath 4. The actuating shaft 400 may preferably extend through a second shaft hole 464 formed in the rear cover plate 460 of the proximal housing 12 and preferably abuts an interior portion of the cavity 30 provided on the proximal housing 12. An endoscope hole 466 may preferably be provided on a portion of the rear cover plate 460 radially separated from the longitudinal axis of the working head assembly 2 to guide the endoscope 8 into the cut-out 29 of the proximal housing 12. The endoscope 8 may preferably be received into the endoscope hole 466 from an endoscope lumen 40 provided within the sheath 4 which is preferably disposed along a periphery of the sheath.

FIG. 9 d shows a perspective cut-away view of the sheath 4 with the various devices (i.e., the two grasping devices 108, the drive cable 100, the actuating cable 450, and the endoscope 8) extending there through. Each of the various devices are further enclosed by one of a plurality of tubes 510 which allow either a rotational movement (for the cables 100, 450) or a longitudinal (for the two grasping devices 108 and the endoscope 8) movement therein. Similar to the sheath 4, the plurality of tubes extend from a proximal end coupled to the control handle 6, to a distal end coupled to the working head assembly 2. The plurality of tubes 510 provide protection against damage due to, for example, abrasion, and provide an isolated path through the sheath 4 which prevents tangling between the various devices.

FIG. 18 shows a cross-section of the control handle 6 which may be used in conjunction with a resectioning device of the invention. The control handle 6 may preferably be substantially “Y” shaped, with a first branch 500 for operating the actuating mechanism 104 and a second branch 502 for operating the drive mechanism 102 and a body 520. A receiving hole 512 runs longitudinally through the center of the body 520 for receiving the endoscope 8 there through. A first force transferring mechanism 504 is coupled to an actuating control knob 508, and extends axially through the first branch 500, through the body 520, where it is coupled to the actuating cable 450 which extends through the sheath 4 to connect to the actuating mechanism 104. A second force transferring mechanism 506 is coupled to a drive control knob 510, and extends axially through the second branch 502, through the body 520, where it is coupled to the drive cable 100 which extends through the sheath 4 to the drive mechanism 102. Those skilled in the art will understand that the control handle may be designed in any variety of shapes to accommodate, for example, different hand sizes, comfort, etc. In addition, different force transferring methods may also be used instead of a knob such as, for example, actuating levers, etc.

In operation, the user applies a rotational force to one of the control knobs 508 and 510, the rotational force is transferred through a respective one of the force transferring mechanisms 504 and 506 which then transfers rotational force to a respective one of the drive cable 100 and actuating cable 450, thereby operating the actuating mechanism 104 or the drive mechanism 102 as described above.

FIG. 11 shows a device according to a second embodiment of the Present invention in which like reference numerals identify the same elements.

The anvil member 10 of this embodiment preferably has a substantially circular or elliptical cross-section and is gradually tapered from the proximal face 14 to its distal end 16, forming a bullet-like structure. This tapered shape allows the device to be more easily inserted into the patient's body as the distal end 16 has a smaller cross-sectional size than in the first embodiment. Those skilled in the art will understand that the anvil member 10 may have other tapered shapes besides a bullet-like structure without departing from the scope of the present invention.

Instead of providing the cut-out 13 shown in the first embodiment to receive the endoscope 8 therein, a substantially cylindrical first endoscope lumen 13 extends axially through the center of the anvil member 10. The distal end 16 of the anvil member 10 may preferably have a beveled edge 54 adjoining the first endoscope lumen 13 to allow for an expanded field of forward vision via the endoscope 8.

The proximal housing 12 may preferably have a cross section corresponding in size and shape to the cross section of the proximal face 14 of the anvil member 10 (i.e., substantially circular or elliptical). In this embodiment, the cavity 30 in the first embodiment has been omitted and a substantially cylindrical second endoscope lumen 52 extends axially through the center of the proximal housing 12.

However, as in the previous embodiment, two grasped holes 32, 33 extend axially through the proximal housing. The two grasped holes 32 and 33 may preferably be disposed between the mounting holes 26 a and 26 b since the first endoscope lumen 13 now extends through the axial center of the proximal housing 12. In addition, the grasped holes 32, 33 in this embodiment may preferably have a substantially circular cross-section. However, those skilled in the art will understand that the cross-sectional shape of the grasped holes 32 and 33 may be selected to, for example, accommodate another type of device.

A receiving sleeve 55 is provided on the proximal end 12 b of the proximal housing 12 for receiving the endoscope 8 and for guiding the endoscope 8 into the proximal housing 12. The receiving sleeve 55 may preferably have a first section 56 and a second section 58. The first section 56 and second section 58 may preferably both have an annular cross-section forming a continuous center hole 59 there through. The center hole 59 has a diameter which preferably corresponds to the diameter of the receiving hole 52 BO that the endoscope 8 may be continuously received through the center hole 59 into the second endoscope lumen 52 in the proximal housing 12. The second section 58 preferably has a thicker wall than the first section 56, such that an annular ring formed by the cross-section of the second sections 58 has a larger width than an annular ring formed by the cross-section of the first section 56.

In contrast to the endoscope lumen 40 disposed along the periphery of the sheath 4 as shown in FIG. 1, the endoscope lumen 40 in this embodiment preferably runs along an axial center of the sheath 4, so that when the sheath 4 is coupled to the working head assembly 2, a substantially continuously aligned path is formed through the center hole 59, through the second endoscope lumen 52, and through the first endoscope lumen 13. The actuating shafts 400 and 105 and the drive cables 450 and 102 are then located concentric to the endoscope lumen 40 in the sheath 4.

FIG. 12 shows a device according to a third embodiment of the present invention. The proximal face 14 of the anvil member 10 of this embodiment has a cross section similar to the crescent-shaped cross-section of the anvil member 10 of the device of FIG. 1. Thus, the anvil member 10 has two horns 22 a and 22 b formed on either side of a cut-out 13 which extends axially through the anvil member 10 from the proximal face 14 to the distal end 15 to receive the endoscope 8 therein. As with the device of FIG. 11, the cross-sectional size of the anvil member 10 diminishes in overall size from a maximum at the proximal face 14 to a minimum size at the distal end 15, and the horns 22 a and 22 b become less pronounced from the proximal face 14 to the distal end 15. In a side view, the anvil member 10 becomes gradually tapered from the proximal end 14 to the distal end 16.

As in the device of FIG. 11, the tapered shape of the anvil member 10 of the device of FIG. 12 allows for easier insertion of the device into the patient's body. In contrast to the second embodiment, the cut-out 13 provides a larger field of vision via the endoscope 8 as the anvil member does not totally enclose the cut-out 13. And, as in the first embodiment, two substantially cylindrical mounting shafts 20 a and 20 b are coupled to the proximal face 14 of the anvil member 10 on horns 22 a and 22 b and are received within the mounting holes 26 a and 26 b, respectively.

In contrast to the previous embodiments, the proximal housing 12 in this embodiment may preferably have a substantially oval cross-sectional shape. This shape of the proximal housing 12 is formed by extending the proximal housing 12 shown in FIG. 1 around the cutout 29 to create the substantially cylindrical second endoscope lumen 52. The oval shape allows the second endoscope lumen 52 to be offset from the axial center of the proximal housing 12 and aligned with the first endoscope lumen 13. This offset of the second lumen 52 allows the cavity 30 to be provided adjoining the blade slit 36. In all other material respects, the proximal housing 12 in this embodiment is substantially identical to the proximal housing 12 illustrated in FIG. 1.

FIG. 13 shows a device according to a fourth embodiment of the present invention. This embodiment is substantially similar to the embodiment shown in FIG. 12. However, the proximal face 14 of the anvil member 10 in this embodiment has a substantially oval-shaped cross section corresponding to the proximal housing 12. The anvil member 10 is tapered towards the distal end 16 to form a substantially bullet-like structure having an oval-shaped cross-section. The cut-out 13 shown in FIG. 12 may preferably be enclosed within the anvil member 10 and thereby forms an extension of the first endoscope lumen 13.

A substantially semicircular shield 31 extends from the proximal face 14 of the anvil member 10 and shields a hemispherical portion of the gap formed between the anvil member 10 and the proximal housing 12. The shield 31 allows a tissue section to be drawn primarily in the gap between the staple-forming grooves 19 and the staple slits 34 with minimal spill-over into the rest of the gap.

A recessed groove 35 may preferably be formed around a portion of the proximal housing 12 for slidably receiving the shield 31 therein. The recessed groove 35 may preferably have a size and shape substantially corresponding to the size and shape of the shield 31 so that when the anvil member 10 is in its proximal most position, the shield 31 is received within the recessed groove 35 to form a substantially completely continuous outer surface of the proximal housing 12.

In operation, the user may utilize suction through the endoscope 8 to draw a tissue section into the gap between the anvil member 10 and the proximal housing 12. In such a situation, the shield 31 prevents a portion of the tissue section or loose debris from being pulled into the area around the mounting shafts 20 a and 20 b which may otherwise interfere with the axial movement of the mounting shafts 20 a, 20 b. In addition, the shield 31 also serves to direct the pulling force of the suction to pull tissue primarily in the gap between the staple forming grooves 19 and the staple slits 34.

FIGS. 14 a and 14 b show a device according to a fifth embodiment of the present invention in which the working head assembly 2 is coupled to the endoscope 8 without the sheath 4. As described above, distal ends 500 a of control cables 500 (i.e., drive cable 100 and actuating cable 450) may preferably be coupled to the working head assembly 2 while proximal ends 500 b of the control cables 500 are coupled to the control handle 6 as in the previous embodiments. However, instead of using a flexible sheath 4 to receive the control cables 500 and the endoscope 8, the control cables 500 are inserted into respective tubes 510. Each of the tubes 510 should have a sufficient cross-section to allow the control cables 500 to rotate within the tubes 510. The tubes 510 are then fastened at various predetermined points along their lengths to the endoscope 8 by a plurality of fasteners 502. Those skilled in the art will understand that many different types of fasteners may be used either alone or in combination for this purpose so long as the fasteners do not impede the steering of the endoscope 8 or the rotation of the cables 500. Those skilled in the art will understand that tape (e.g., surgical, electrical, etc.), electrical cable, rubber bands, other belt-style fasteners, etc. may be used as fasteners.

FIGS. 16-18 illustrate alternative configurations of the blade housing 74 b and it will be understood that similar alternative embodiments may be implemented for the blade housing 74 a.

The blade slit 36 continues through the blade housing 74 b into housing portion 84 b which extends from a forward end at which the blade slit 36 enters the blade housing 74 b to a rearward end where the blade slit 36 and the housing portion 84 b terminate. A shield receiving slit 480 extends through the blade housing 74 b substantially perpendicular to the housing portion 84 b between the forward and rearward ends thereof.

After an organ section has been stapled between the anvil member 10 and the proximal housing 12, and the blade 202 is drawn through the stapled tissue, there may be a problem if tissue stretches along with the blade 202 into the housing portion 84 b without being completely severed. Withdrawal of the resectioned tissue might then lead to tearing of the tissue which is to remain in place.

As seen in FIG. 17, a flexible breakaway shield 482 having a shape and size substantially corresponding to the shape and size of the shield receiving slit 480 is inserted into the shield receiving slit 480. After entering the housing portion 84 b, the cutting blade 202 contacts the shield 482 and further progress of the blade 202 deforms the shield 482 until the shield 482 is cut in half. When the shield 482 is cut in half, each half snaps back pulling the tissue in a direction opposite the direction of travel of the blade allowing the cutting blade 202 to completely sever the tissue.

FIG. 18 shows a second alternative arrangement in which a flexible gate 484, having a first gate half 484 a and a second gate half 484 b, may be removably or fixedly mounted within the shield receiving slit 480. Each of the halves 484 a and 484 b may preferably be mounted within a respective half of the shield receiving slit 480, so that a small gap formed there between substantially corresponds in width to the width of the cutting blade 202. The wiping action in a direction opposed to the direction of travel of the blade 202 is substantially the same as that of the shield 482 without requiring the severing and replacement of the shield 482 after each use.

FIGS. 19 a and 19 b show a third alternative arrangement in which a pair of tissue blockers 600 and 602 facilitate the cutting of the resectioned tissue. Although, the following discussion will focus on the first tissue blocker 600, those skilled in the art will understand that a similar arrangement may be provided on the second tissue blocker 602.

As shown in FIG. 19 a, the first tissue blocker 600 is composed of a first rectangular bar 610 and a second rectangular bar 612 situated at a first end 21 a of the guiding slit 21. The first rectangular bar 610 has a first base 610 a and the second rectangular bar 612 has a second base 612 a, which are both fixedly coupled to the proximal face 14 of the anvil member 10 and arranged so that the bases 610 a, 612 b straddle both sides of the guiding slit 21 with a gap formed there between corresponding to the width of the guiding slit 21.

A first slot 614 a is provided in the first base 610 a of the first rectangular bar 610, and a second slot 614 b is provided in the second base 612 a of the second rectangular bar 612 so that when the rectangular bars 610, 612 are coupled to the anvil member 10, the flexible breakaway shield 482 (shown in FIG. 17) may be disposed within the slots 614 a, 614 b. As shown in FIG. 19 c, a pair of L-shaped holes 620, 622 are provided on both ends of the blade slit 30 on the distal end 12 a of the proximal housing 12. The L-shaped holes 620, 622 extend longitudinally within the proximal housing 12 to receive the rectangular bars 610, 612 therein when the anvil member 10 is coupled to the proximal housing 12.

This arrangement operates similarly to the arrangement shown in FIG. 17, so that the wiping action of the shield 482 in a direction opposite to a movement of the blade 202 allows the blade 202 to completely cut through the resectioned tissue. Although the shield 482 is initially a single piece in a first operation of the device, the shield 482 may be re-used without replacement in further operations with minimal diminishment of its effectiveness.

FIG. 20 shows a device according to a sixth embodiment of the present invention in which like reference numerals identify the same elements. The sheath 4 is substantially more rigid and shorter than in previous embodiments. Although this decreases the effective operative range of the device, the rigidity of the sheath 4 increases its overall structural strength, allowing greater forces to be transferred there through to the working head assembly 2 than in the previous embodiments. The cables 100, 450 driving the various mechanisms 102, 104 may then need to be stronger and stiffer in order to accommodate the increased forces. As a result of these changes, the overall size of the working head assembly 2 may then be increased to, for example, treat lesions that may be too large for the devices according to the previous embodiments to treat in a single procedure.

FIGS. 21-25 show a device according to a seventh embodiment of the present invention in which the working head assembly 2 comprises the anvil member 10, a stapler member 17, and a connecting adapter 25. As shown in FIG. 21, the anvil member 10 and the stapler member 17 preferably have substantially semi-circular shapes complementary to one another such that, when they are positioned adjacent to each other, they form a substantially annular clamp-like device (as shown in FIG. 23). The anvil member 10 and the stapler member 17 are pivotally connected via a substantially cylindrical hinge-pin 60 which is provided on a distal end 25 a of the connecting adapter 25. A proximal end 25 b of the connecting adapter 25 may preferably be coupled to the sheath 4 in a manner similar to that in which the proximal housing 12 is connected to the sheath 4 in the previous embodiments. Those skilled in the art will understand that the shape of the anvil member 10 and the stapler member 17 may be modified to accommodate specific needs or applications without departing from the scope of the present invention.

As shown in FIG. 22, a plurality of first ring-like extensions 10 b are formed on a first end 10 a of the anvil member 10. The first extensions 10 b may preferably be separated a predetermined distance from one another to form a plurality of spaces in which a corresponding plurality of second ring-like extensions 17 b formed on a first end 17 a of the stapler member 17 are accommodated. The first extensions 10 b may substantially correspond in shape and size to the second ring-like extensions 17 b so that when the first anvil end 10 a and the first stapler end 17 a are engaged, an alternating arrangement of first and second extensions 10 b, 17 b is formed in which the holes of each of the first and second extensions 10 b, 17 b are substantially aligned to form a continuous hole in which a hinge-pin 60 is received. Thus, the hinge-pin 60 and the first and second extensions 10 b, 17 b form a hinge which allows the anvil member 10 and the stapler member 17 to pivot about the hinge-pin 60. A locking ring 62 may preferably be attached to a distal end 61 of the hinge-pin 60 to secure the first and second extensions 10 b, 17 b to the hinge-pin 60.

A first anchoring joint 23 a is formed on an interior face 10 i of the anvil member 10. The first anchoring joint 23 a may preferably have a substantially triangular cross-section viewed along the longitudinal axis of the working head assembly 2. However, a side of the first anchoring joint 23 a that is attached to the anvil member 10 may preferably be convex in shape complementary to the concave shape of the interior face 10 i of the anvil member 10. A substantially similar second anchoring joint 23 b is formed on an interior face 17 i of the stapler member 17 having a size and shape corresponding to the size and shape of the anchoring joint 23 a.

As shown in FIG. 23, first and second coupling elements 64 a, 64 b are disposed on respective anchoring joints 23 a, 23 b to couple the anchoring joints 23 a, 23 b to two rod links 150 a, 150 b, respectively. The rod links 150 a, 150 b provide a rigid coupling between the anchoring joints 23 a, 23 b and a distal end 154 of a push rod 152. Thus, a longitudinal force in a distal or proximal direction applied to the push rod 152 is transferred to the anchoring joints 23 a, 23 b, and thereby to the anvil member 10 and the stapler member 17.

In operation, when a distally directed pushing force is applied to the push rod 152, the force is transferred through the link rods 150 a, 150 b to the anvil member 10 and the stapler member 17 via the respective anchoring joints 23 a, 23 b, gradually separating an anvil head 10 c on the anvil member 10 from a stapler head 17 c on the stapler member 17 until they reach a tissue receiving position. Similarly, when a proximally directed pulling force is applied to the push rod 152, the anvil head 10 c and the stapler head 17 c are drawn toward one another until they reach a stapling position, in which the anvil head 10 c and the stapler head 17 c are adjacent to one another separated by a narrow gap. As the anvil head 10 c and the staler head 17 c are drawn together by the push rod 152, a stabilizer tongue 308 extending from the stapler head 17 c of the stapler member 17 is gradually received within a stabilizing groove 304 on the anvil head 10 c. This tongue/groove arrangement provides a guide and a securing/stabilization mechanism for the anvil member 10 and the stapling member 17.

The anvil head 10 c is disposed on a second end 10 e of the anvil member 10 that is opposite to the first end 10 a thereof. The anvil head 10 c may preferably have a substantially rectangular cross-section larger than a cross-sectional size of the rest of the anvil member 10. The anvil head 10 c has an anvil face 10 d on which a plurality of staple-forming grooves 19 may preferably be arranged in two offset, substantially straight lines. In addition, a substantially straight guiding slit 21 may preferably extend substantially along the center of the anvil face 10 d, substantially parallel to the lines of staple-forming grooves 19, while the stabilizing groove 304 is preferably formed along a distal side of the anvil face 10 d for receiving the stabilizer tongue 308. The stabilizing groove 304 may preferably have a shape and size substantially corresponding to the stabilizing tongue 308 so that the stabilizing tongue 308 is snugly received within the stabilizing groove 304 when the anvil member 10 and the stapler member 17 are in the stapling position.

As shown in FIG. 23 a, the stapler head 17 c is formed on a second end 17 e of the stapler member 17 opposite to the first end 17 a thereof, and preferably has a cross section corresponding, at least in the area adjacent to a stapler face 17 d, to the size and shape of the anvil head 10 c. A plurality of staple slits 34 are arranged on the stapler face 17 d in positions corresponding to the position of the staple-forming grooves 19 on the anvil head 10 c so that when the stapler face 17 d and anvil face 10 d are positioned adjacent to each other, each of the plurality of staple slits 34 is substantially aligned with a corresponding one of the plurality of staple forming groove 19. Additionally, a substantially straight blade slit 36 extends across the stapler face 17 d corresponding to the guiding slit 21 on the anvil head 10 c so that when the stapler head 17 c and the anvil head 10 c are positioned adjacent to one another, the blade slit 36 is substantially aligned with the guiding slit 21.

As shown in FIG. 23, the distal end 25 a of the connecting adapter 25 preferably has a cross-section corresponding to the shape and size of the peripheral surface of the annular clamp-like shape formed by the anvil member 10 and the stapler member 17 so that a substantially smooth, continuous outer surface is formed by the anvil member 10, the stapler member 17, and the connecting adapter 25 when the anvil member 10 and the stapler member 17 are in the stapling position. The connecting adapter 25 is preferably gradually tapered from the distal end 25 a to the proximal end 25 b thereof, and the proximal end 25 b may then be coupled to the sheath 4 as shown in FIG. 24. As further shown in FIG. 24, a substantially cylindrical endoscope lumen 52 preferably extends axially through the center of the connecting adapter 25 for receiving a conventional endoscope 8 there through. The connecting adapter 25 may also have a substantially cylindrical rod hole 322 extending axially along the periphery of the connecting adapter 25 extending through an area adjacent to the hinge-pin 60, for receiving the push rod 152 therein.

As shown in the cut-away view of FIG. 25, a track 350 is provided within the stapler head 17 c extending within the stapler head 17 c from an area adjacent to a distal end 352 of the stapler head 17 c to an area adjacent to a proximal end 354 thereof. FIG. 26 shows a cutaway view of the stapler head 17 c showing the track 350 having a substantially L-shaped cross-section. The track 350 may preferably be situated so that a first leg 350 a of the track 350 extends substantially beneath the plurality of staple slits 34 on the staple face 17 d, and a second leg 350 b of the track 350 extends substantially beneath the blade slit 21 on the staple face 17 d.

In a first configuration shown in FIG. 25, a wedgesled 402 is provided (instead of the wedge 402 described in the previous embodiments) on a distal end 350 a of the track 350. The wedge-sled 402 has a cut-out in a corner forming a cam surface 412 thereon and a blade handle 408. This provides the wedge-sled 402 with a substantially L-shaped cross-section substantially corresponding to the cross-sectional shape of the track 350. The wedge-sled 402 is arranged in the track 350 so that the cam surface 412 is substantially disposed in the first leg 350 a of the track facing toward the plurality of staple slits 34. Furthermore, the wedge-sled 402 is arranged in the track 350 so that the blade handle 408 is substantially disposed in the second leg 350 b beneath the blade slit 21. Thus, when the cutting blade 202 is coupled to the blade handle 408, the cutting blade 202 extends out of the blade slit 21 as in the previous embodiments. As shown in FIG. 26, the stabilizing tongue 308 has a receiving slit 309 for receiving the cutting blade 202 therein when the wedgesled 402 is positioned at the distal end 350 a of the track 350. This prevents unintentional cutting of tissue as the device is inserted and guided within the organ.

As shown in FIG. 25, an actuating cable 450 for operating the stapler head 17 c is coupled to the leading edge 402 d of the wedge-sled 402 and extends through the track 350, through a tube 332 (which is coupled to the proximal end 354 of the stapler head 17 c and extends through the sheath 4 to the control handle) of the plurality of tubes 510 (shown in FIG. 9 d), and is then coupled to the control handle 6 (not shown).

In operation, the wedge-sled 402 is initially positioned at the distal end 350 a of the track 350 with the blade 202 received within the receiving slit 309 of the stabilizing tongue 308 as the operator maneuvers the device to a desired location within the body. While the device is being maneuvered to the desired location, the anvil member 10 and the stapler member 17 are located adjacent to each other in the stapling position. When the desired position is reached, the operator pushes the push rod 152 distally to separate the anvil member 10 and the stapler member 17 into the tissue receiving position. Then the operator draws the portion of tissue to be resectioned into the gap between the stapler member 17 and the anvil member 10 and draws the push rod 152 proximally to return the anvil member 10 and the stapler member 17 to the stapling position, gripping the tissue to be resected within the gap. The operator then pulls actuating cable 459 proximally, drawing the wedge-sled 402 towards the proximal end 350 b of the track 350. As the cam surface 412 on the wedge-Bled passes beneath each one of the plurality of staple slits 34, the cam surface 412 drives each one of a plurality of staple drivers 472 (each being disposed within a corresponding one of the staple slits 34) sequentially driving a plurality of staples out of the staple slits 34 to staple the tissue gripped between the anvil head 10 c and the stapler head 17 c. In addition, the cutting blade 202 coupled to the blade handle 408 of the wedge-sled 402 is pulled through the blade slit 21 to resection the tissue which has now been stapled off from the organ.

When the tissue has been resectioned, the operator pushes the operating cable 450 distally to return the cutting blade 202 to the receiving slit 309 of the stabilizing wedge 308. The device may then be withdrawn from the body.

As shown in FIGS. 23 and 25, the anvil member 10 and the stapler member 17 have a tissue receiving position shown in FIG. 25, and a stapling position shown in FIG. 23. Therefore, it is necessary to allow the actuating cable 450 disposed within the tube 332 and received within the stapler head 17 c to correspondingly move with the stapler member 17. Accordingly, a channel 330 is provided in the connecting adapter 25 to receive the tube 332 therein. The channel 330 may preferably be formed within the connecting adapter 25 to substantially correspond to the arc path along which the tube 332 is pulled by the stapler member 17, as the stapler member 17 moves between the tissue receiving and the stapling positions. Thus, the channel minimizes bending and crimping of the tube 332.

Those skilled in the art will understand that although the proximal housing 12 in any of the embodiments may preferably be composed of a metallic-type material, the proximal housing 12 may also be composed of a clear plastic-type material which would allow the user to operate the working head assembly 2 under visual observation by partially withdrawing the endoscope 8 into the second endoscope lumen 52 in the proximal housing 12. The user could then look through the walls of the endoscope lumen 52 into the proximal housing 12 to, for example, observe whether each of the plurality of staple drivers 472 have been actuated. In addition, the user may also observe whether the wedge 402 shown in FIGS. 10 a and 10 b is locked into the blade portion 420 as described above. Alternatively, selected portions of the proximal housing 12 may be composed of the clear plastic-type material providing a “window” to view through the proximal housing 12.

Those skilled in the art will also understand that although the above-described embodiments show mechanical force transmission between the control handle and the working head assembly, this device could alternatively include an electronic control for receiving input from an operator coupled to a series of motors in the working head assembly. Those skilled in the art will further understand that the relative positioning of the stapling mechanisms and the position adjusting mechanisms to each other may be reversed, placing the stapling mechanisms in a distal-most position in relation to the position adjusting mechanism.

In a different embodiment, the FTRD according to the present invention includes a removable integrated surgical staple retainer that secures the staples during shipping and can be used to gauge the outermost diameter of an endoscope. The integrated surgical staple retainer is preferably mounted between the proximal housing 12 and the anvil member 10 of the FTRD when in position to retain the staples.

In one embodiment, shown in FIG. 27, the integrated surgical staple retainer 623 can have a calibrating portion 624 and a retaining portion 626. The calibrating portion 624 defines a circular opening 625 having a diameter substantially equal to a diameter of the working channel formed in the head assembly 2 of the full thickness resectioning device 628. The retaining portion 626 can have positioning elements that include protrusions such as ridges 627, which can be hollow, and which hold the integrated surgical staple retainer 623 in position relative to the head assembly 2. In one exemplary embodiment, the integrated surgical staple retainer 623 is placed between the proximal housing 12 and the anvil member 10, which are then moved near one another. The ridges 627 protrude behind the edge of anvil member 10, preventing removal of the integrated surgical staple retainer 623. In an alternative embodiment, the retaining portion 626 can include a groove, a flat surface, or any other feature to mechanically keep the integrated surgical staple retainer 623 in place, instead of a plurality of hollow ridges.

The calibrating portion 624 can be located adjacent to, to either side of, in front, or behind the retaining portion 626 as long as the calibrating portion does not interfere with the retaining function. In one embodiment of the present invention, the calibrating portion 624 can be inside the arc of the retaining portion 626. As seen in FIG. 28, in another embodiment, the retaining portion 626 can be to the side of the calibrating portion 624. The integrated surgical staple retainer 623 can also have a grasping portion 630 which can be located adjacent to, to either side of, in front, or behind the retaining or calibrating portion. As seen in FIG. 28, in one embodiment, the grasping portion 630 is adjacent to the retaining portion 626 of the integrated surgical staple retainer opposite to the calibrating portion 624. An advantage of this particular embodiment is that the FTRD 628 does not need to be opened in order to remove and expose the calibrating portion 624. The retaining portion 626 remains in place while the circular opening 615 is slid over the length of an endoscope 8 to gauge the diameter of the endoscope. In this manner, the staples are less likely to fall out of housing 12 while the device is being handled.

As shown in the exemplary embodiment of FIG. 29, in relation to the FTRD 628, the retaining portion 626 of the integrated surgical staple retainer 623 can be placed between the proximal housing 12 and the anvil member 10 of the FTRD 628. In one embodiment, the integrated surgical staple retainer 623 can be placed between the staple slits 34 of the proximal housing 12 and the staple forming grooves 19 of the anvil member 10. The calibrating portion 624 can be placed inside a cavity defined by head assembly 2. Alternatively, the calibrating portion 624 can extend outside of head assembly 2, or can be in any non-interfering position.

As shown in FIG. 30, to use the retaining portion 626 of the integrated surgical staple retainer 623, the distance 629 between the anvil member 10 and the proximal member 12 is minimized such that the plurality of ridges 627 of the retaining portion 626 fill the staple forming grooves 19 of the anvil member 10. Alternatively, ridges 627 are retained in place by the circumference of anvil member 10. An underside surface 640 of integrated surgical staple retainer 623 thus fully covers the staple slits 34 of the proximal housing 12. In an alternative exemplary embodiment, a flat surface of the retaining portion 626 contacts the staple forming grooves 19 and also covers the staple slits 34. In that case, the integrated surgical staple retainer 623 can be held in place by different shaped protrusions that engage the staple forming grooves 19, or more generally, that engage the anvil member 10 so that integrated surgical staple retainer 623 remains in position relative to the head assembly 2.

FIG. 31 shows the use of the calibrating portion 624 of the integrated surgical staple retainer 623. The circular opening 625 is slid over the length of an endoscope 8 to ensure a maximum diameter 630 never exceeds the diameter of opening 625. If the entire endoscope 8 is able to slide through the circular opening 625, this indicates that the endoscope will be able to slide through a working channel of the FTRD 628.

The use of the integrated surgical staple retainer according to the present invention includes, for example, the following steps. The FTRD 628 is unpacked from its shipping package so that a user can hold the grasping portion of the integrated surgical staple retainer 623 to remove it from between the proximal housing 12 and the anvil member 10 of the FTRD. The user then slides the calibrating portion 624 of the integrated surgical staple retainer along the length of an endoscope 8. If the endoscope 8 slides smoothly through the opening 625 of the calibrating portion 624 of the integrated surgical staple retainer 623, the user has affirmative knowledge that the endoscope will be able to slide through the working channel of that FTRD 628 without binding, even if the maximum diameter 630 is greater than a nominal diameter of endoscope 8

Although the present invention has been described with respect to several exemplary embodiments, those skilled in the art will understand that there are many other variations of the above described embodiments within the teaching of the present invention, which is to be limited only be the claims appended hereto. 

1. A method of gauging an outermost diameter of an endoscope for use in an FTRD comprising: removing an integrated surgical staple retainer from between an anvil member and a proximal housing of an FTRD to release surgical staples held in the proximal housing; sliding through a calibrating portion of the integrated surgical staple retainer an endoscope; and determining that a maximum diameter of the endoscope fits through the calibrating portion.
 2. The method of gauging the outermost diameter of an endoscope for use in an FTRD according to claim 1 further comprising the preliminary step of increasing a distance between the anvil member and the proximal housing.
 3. A method of retaining staples in a FTRD comprising: placing a retaining portion of an integrated surgical staple retainer between a proximal housing and an anvil member of the FTRD; and minimizing the distance between the anvil member and the proximal housing such that the retaining portion remains in position relative to a head assembly of the FTRD.
 4. The method of retaining staples in a FTRD according to claim 3 further comprising; placing a retaining portion of the integrated surgical staple retainer between staple slits of a proximal housing of the FTRD and staple forming grooves of an anvil member of the FTRD, the retaining portion being adjacent to a calibrating portion of the integrated surgical staple retainer; and minimizing the distance between the anvil member and the proximal housing such that the retaining portion contacts the staple forming grooves of the anvil member and covers the staple slits of the proximal housing. 